INF553-Homework 4 GirvanNewman Algorithm using Spark Framework Solved

In this assignment, you will explore the spark GraphFrames library as well as implement your own GirvanNewman algorithm using the Spark Framework to detect communities in graphs. You will use the ub_sample_data.csv dataset to find users who have a similar business taste. The goal of this assignment is to help you understand how to use the Girvan-Newman algorithm to detect communities in an efficient way within a distributed environment. 2. Requirements 2.1 Programming Requirements a. You must use Python to implement all tasks. There will be 10% bonus for each task if you also submit a Scala implementation and both your Python and Scala implementations are correct. b. You can use the Spark DataFrame and GraphFrames library for task1, but for task2 you can ONLY use Spark RDD and standard Python or Scala libraries. (ps. For Scala, you can try GraphX, but for the assignment, you need to use GraphFrames.) 2.2 Programming Environment Python 3.6, Scala 2.11 and Spark Datasets You will continue to use Yelp dataset. We have generated a sub-dataset, ub_sample_data.csv, from the Yelp review dataset containing user_id and business_id. You can download it from Blackboard. 4. Tasks 4.1 Graph Construction To construct the social network graph, each node represents a user and there will be an edge between two nodes if the number of times that two users review the same business is greater than or equivalent to the filter threshold. For example, suppose user1 reviewed [business1, business2, business3] and user2 reviewed [business2, business3, business4, business5]. If the threshold is 2, there will be an edge between user1 and user2. If the user node has no edge, we will not include that node in the graph. NOTICE: In this assignment, the filter threshold is 7. 4.2 Task1: Community Detection Based on GraphFrames (2 pts) In task1, you will explore the Spark GraphFrames library to detect communities in the network graph you constructed in 4.1. In the library, it provides the implementation of the Label Propagation Algorithm (LPA) which was proposed by Raghavan, Albert, and Kumara in 2007. It is an iterative community detection solution whereby information “flows” through the graph based on underlying edge structure. For the details of the algorithm, you can refer to the paper posted on the Blackboard. In this task, you do not need to implement the algorithm from scratch, you can call the method provided by the library. The following websites may help you get started with the Spark GraphFrames: https://docs.databricks.com/spark/latest/graph-analysis/graphframes/user-guide-python.html https://docs.databricks.com/spark/latest/graph-analysis/graphframes/user-guide-scala.html 4.2.1 Execution Detail The version of the GraphFrames should be 0.6.0. For Python: • In PyCharm, you need to add the sentence below into your code pip install graphframes os.environ["PYSPARK_SUBMIT_ARGS"] = ( "--packages graphframes:graphframes:0.6.0-spark2.3-s_2.11") • In the terminal, you need to assign the parameter “packages” of the spark-submit: --packages graphframes:graphframes:0.6.0-spark2.3-s_2.11 For Scala: • In Intellij IDEA, you need to add library dependencies to your project “graphframes” % “graphframes” % “0.6.0-spark2.3-s_2.11” “org.apache.spark” %% “spark-graphx” % sparkVersion • In the terminal, you need to assign the parameter “packages” of the spark-submit: --packages graphframes:graphframes:0.6.0-spark2.3-s_2.11 For the parameter “maxIter” of LPA method, you should set it to 5. 4.2.2 Output Result In this task, you need to save your result of communities in a txt file. Each line represents one community and the format is: ‘user_id1’, ‘user_id2’, ‘user_id3’, ‘user_id4’, … Your result should be firstly sorted by the size of communities in the ascending order and then the first user_id in the community in lexicographical order (the user_id is type of string). The user_ids in each community should also be in the lexicographical order. If there is only one node in the community, we still regard it as a valid community. Figure 2: community output file format 4.3 Task2: Community Detection Based on Girvan-Newman algorithm  In task2, you will implement your own Girvan-Newman algorithm to detect the communities in the network graph. Because you task1 and task2 code will be executed separately, you need to construct the graph again in this task following the rules in section 4.1. You can refer to the Chapter 10 from the Mining of Massive Datasets book for the algorithm details. For task2, you can ONLY use Spark RDD and standard Python or Scala libraries. 4.3.1 Betweenness Calculation  In this part, you will calculate the betweenness of each edge in the original graph you constructed in 4.1. Then you need to save your result in a txt file. The format of each line is (‘user_id1’, ‘user_id2’), betweenness value Your result should be firstly sorted by the betweenness values in the descending order and then the first user_id in the tuple in lexicographical order (the user_id is type of string). The two user_ids in each tuple should also in lexicographical order. You do not need to round your result. Figure 3: betweenness output file format 4.3.2 Community Detection  You are required to divide the graph into suitable communities, which reaches the global highest modularity. The formula of modularity is shown below: According to the Girvan-Newman algorithm, after removing one edge, you should re-compute the betweenness. The “m” in the formula represents the edge number of the original graph. The “A” in the formula is the adjacent matrix of the original graph. (Hint: In each remove step, “m” and “A” should not be changed). If the community only has one user node, we still regard it as a valid community. You need to save your result in a txt file. The format is the same with the output file from task1. 4.4 Execution Format Execution example: Python: spark-submit --packages graphframes:graphframes:0.6.0-spark2.3-s_2.11 firstname_lastname_task1.py spark-submit firstname_lastname_task2.py Scala: spark-submit --packages graphframes:graphframes:0.6.0-spark2.3-s_2.11 –class firstname_lastname_task1 firstname_lastname_hw4.jar spark-submit –class firstname_lastname_task2 firstname_lastname_hw4.jar Input parameters: 1. : the filter threshold to generate edges between user nodes. 2. : the path to the input file including path, file name and extension. 3. : the path to the betweenness output file including path, file name and extension. 4. : the path to the community output file including path, file name and extension. Execution time: The suggested overall runtime of your task1 (from reading the input file to finishing writing the community output file) is 200 seconds. The overall runtime of your task2 (from reading the input file to finishing writing the community output file) should be less than 200 seconds. If your runtime is between 200 seconds and 300 seconds, there will be 50% penalty. If your runtime exceeds 300 seconds, there will be no point for this task.